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/*
 *
 *   ASM: a very small and fast Java bytecode manipulation framework
 *   Copyright (c) 2000-2007 INRIA, France Telecom
 *   All rights reserved.
 *
 *   Redistribution and use in source and binary forms, with or without
 *   modification, are permitted provided that the following conditions
 *   are met:
 *   1. Redistributions of source code must retain the above copyright
 *      notice, this list of conditions and the following disclaimer.
 *   2. Redistributions in binary form must reproduce the above copyright
 *      notice, this list of conditions and the following disclaimer in the
 *      documentation and/or other materials provided with the distribution.
 *   3. Neither the name of the copyright holders nor the names of its
 *      contributors may be used to endorse or promote products derived from
 *      this software without specific prior written permission.
 *
 *   THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 *   AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 *   IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 *   ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 *   LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 *   CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 *   SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 *   INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 *   CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 *   ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
 *   THE POSSIBILITY OF SUCH DAMAGE.
 */
package org.powermock.api.mockito.repackaged.asm;

/**
 * A {@link MethodVisitor} that generates methods in bytecode form. Each visit
 * method of this class appends the bytecode corresponding to the visited
 * instruction to a byte vector, in the order these methods are called.
 * 
 * @author Eric Bruneton
 * @author Eugene Kuleshov
 */
class MethodWriter implements MethodVisitor {

    /**
     * Pseudo access flag used to denote constructors.
     */
    static final int ACC_CONSTRUCTOR = 262144;

    /**
     * Frame has exactly the same locals as the previous stack map frame and
     * number of stack items is zero.
     */
    static final int SAME_FRAME = 0; // to 63 (0-3f)

    /**
     * Frame has exactly the same locals as the previous stack map frame and
     * number of stack items is 1
     */
    static final int SAME_LOCALS_1_STACK_ITEM_FRAME = 64; // to 127 (40-7f)

    /**
     * Reserved for future use
     */
    static final int RESERVED = 128;

    /**
     * Frame has exactly the same locals as the previous stack map frame and
     * number of stack items is 1. Offset is bigger then 63;
     */
    static final int SAME_LOCALS_1_STACK_ITEM_FRAME_EXTENDED = 247; // f7

    /**
     * Frame where current locals are the same as the locals in the previous
     * frame, except that the k last locals are absent. The value of k is given
     * by the formula 251-frame_type.
     */
    static final int CHOP_FRAME = 248; // to 250 (f8-fA)

    /**
     * Frame has exactly the same locals as the previous stack map frame and
     * number of stack items is zero. Offset is bigger then 63;
     */
    static final int SAME_FRAME_EXTENDED = 251; // fb

    /**
     * Frame where current locals are the same as the locals in the previous
     * frame, except that k additional locals are defined. The value of k is
     * given by the formula frame_type-251.
     */
    static final int APPEND_FRAME = 252; // to 254 // fc-fe

    /**
     * Full frame
     */
    static final int FULL_FRAME = 255; // ff

    /**
     * Indicates that the stack map frames must be recomputed from scratch. In
     * this case the maximum stack size and number of local variables is also
     * recomputed from scratch.
     * 
     * @see #compute
     */
    private static final int FRAMES = 0;

    /**
     * Indicates that the maximum stack size and number of local variables must
     * be automatically computed.
     * 
     * @see #compute
     */
    private static final int MAXS = 1;

    /**
     * Indicates that nothing must be automatically computed.
     * 
     * @see #compute
     */
    private static final int NOTHING = 2;
    /**
     * The class writer to which this method must be added.
     */
    final ClassWriter cw;
    /**
     * The index of the constant pool item that contains the name of this
     * method.
     */
    private final int name;
    /**
     * The index of the constant pool item that contains the descriptor of this
     * method.
     */
    private final int desc;
    /**
     * The descriptor of this method.
     */
    private final String descriptor;
    /**
     * Indicates what must be automatically computed.
     *
     * @see #FRAMES
     * @see #MAXS
     * @see #NOTHING
     */
    private final int compute;
    /**
     * Next method writer (see {@link ClassWriter#firstMethod firstMethod}).
     */
    MethodWriter next;
    /**
     * The signature of this method.
     */
    String signature;

    /**
     * If not zero, indicates that the code of this method must be copied from
     * the ClassReader associated to this writer in {@code cw.cr}. More
     * precisely, this field gives the index of the first byte to copied from
     * {@code cw.cr.b}.
     */
    int classReaderOffset;

    /**
     * If not zero, indicates that the code of this method must be copied from
     * the ClassReader associated to this writer in {@code cw.cr}. More
     * precisely, this field gives the number of bytes to copied from
     * {@code cw.cr.b}.
     */
    int classReaderLength;

    /**
     * Number of exceptions that can be thrown by this method.
     */
    int exceptionCount;

    /**
     * The exceptions that can be thrown by this method. More precisely, this
     * array contains the indexes of the constant pool items that contain the
     * internal names of these exception classes.
     */
    int[] exceptions;
    /**
     * Access flags of this method.
     */
    private int access;
    /**
     * The annotation default attribute of this method. May be null.
     */
    private ByteVector annd;
    /**
     * The runtime visible annotations of this method. May be null.
     */
    private AnnotationWriter anns;
    /**
     * The runtime invisible annotations of this method. May be null.
     */
    private AnnotationWriter ianns;
    /**
     * The runtime visible parameter annotations of this method. May be
     * null.
     */
    private AnnotationWriter[] panns;
    /**
     * The runtime invisible parameter annotations of this method. May be
     * null.
     */
    private AnnotationWriter[] ipanns;
    /**
     * The number of synthetic parameters of this method.
     */
    private int synthetics;
    /**
     * The non standard attributes of the method.
     */
    private Attribute attrs;
    /**
     * The bytecode of this method.
     */
    private ByteVector code = new ByteVector();
    /**
     * Maximum stack size of this method.
     */
    private int maxStack;
    /**
     * Maximum number of local variables for this method.
     */
    private int maxLocals;
    /**
     * Number of stack map frames in the StackMapTable attribute.
     */
    private int frameCount;
    /**
     * The StackMapTable attribute.
     */
    private ByteVector stackMap;
    /**
     * The offset of the last frame that was written in the StackMapTable
     * attribute.
     */
    private int previousFrameOffset;
    /**
     * The last frame that was written in the StackMapTable attribute.
     *
     * @see #frame
     */
    private int[] previousFrame;
    /**
     * Index of the next element to be added in {@link #frame}.
     */
    private int frameIndex;
    /**
     * The current stack map frame. The first element contains the offset of the
     * instruction to which the frame corresponds, the second element is the
     * number of locals and the third one is the number of stack elements. The
     * local variables start at index 3 and are followed by the operand stack
     * values. In summary frame[0] = offset, frame[1] = nLocal, frame[2] =
     * nStack, frame[3] = nLocal. All types are encoded as integers, with the
     * same format as the one used in {@link Label}, but limited to BASE types.
     */
    private int[] frame;
    /**
     * Number of elements in the exception handler list.
     */
    private int handlerCount;
    /**
     * The first element in the exception handler list.
     */
    private Handler firstHandler;
    /**
     * The last element in the exception handler list.
     */
    private Handler lastHandler;
    /**
     * Number of entries in the LocalVariableTable attribute.
     */
    private int localVarCount;
    /**
     * The LocalVariableTable attribute.
     */
    private ByteVector localVar;
    /**
     * Number of entries in the LocalVariableTypeTable attribute.
     */
    private int localVarTypeCount;
    /**
     * The LocalVariableTypeTable attribute.
     */
    private ByteVector localVarType;
    /**
     * Number of entries in the LineNumberTable attribute.
     */
    private int lineNumberCount;
    /**
     * The LineNumberTable attribute.
     */
    private ByteVector lineNumber;
    /**
     * The non standard attributes of the method's code.
     */
    private Attribute cattrs;
    /**
     * Indicates if some jump instructions are too small and need to be resized.
     */
    private boolean resize;

    // ------------------------------------------------------------------------

    /*
     * Fields for the control flow graph analysis algorithm (used to compute the
     * maximum stack size). A control flow graph contains one node per "basic
     * block", and one edge per "jump" from one basic block to another. Each
     * node (i.e., each basic block) is represented by the Label object that
     * corresponds to the first instruction of this basic block. Each node also
     * stores the list of its successors in the graph, as a linked list of Edge
     * objects.
     */
    /**
     * The number of subroutines in this method.
     */
    private int subroutines;
    /**
     * A list of labels. This list is the list of basic blocks in the method,
     * i.e. a list of Label objects linked to each other by their
     * {@link Label#successor} field, in the order they are visited by
     * {@link MethodVisitor#visitLabel}, and starting with the first basic block.
     */
    private Label labels;

    /**
     * The previous basic block.
     */
    private Label previousBlock;

    /**
     * The current basic block.
     */
    private Label currentBlock;

    /**
     * The (relative) stack size after the last visited instruction. This size
     * is relative to the beginning of the current basic block, i.e., the true
     * stack size after the last visited instruction is equal to the
     * {@link Label#inputStackTop beginStackSize} of the current basic block
     * plus stackSize.
     */
    private int stackSize;

    /**
     * The (relative) maximum stack size after the last visited instruction.
     * This size is relative to the beginning of the current basic block, i.e.,
     * the true maximum stack size after the last visited instruction is equal
     * to the {@link Label#inputStackTop beginStackSize} of the current basic
     * block plus stackSize.
     */
    private int maxStackSize;

    // ------------------------------------------------------------------------
    // Constructor
    // ------------------------------------------------------------------------

    /**
     * Constructs a new .
     * 
     * @param cw the class writer in which the method must be added.
     * @param access the method's access flags (see {@link Opcodes}).
     * @param name the method's name.
     * @param desc the method's descriptor (see {@link Type}).
     * @param signature the method's signature. May be null.
     * @param exceptions the internal names of the method's exceptions. May be
     *        null.
     * @param computeMaxs true if the maximum stack size and number
     *        of local variables must be automatically computed.
     * @param computeFrames true if the stack map tables must be
     *        recomputed from scratch.
     */
    MethodWriter(
        final ClassWriter cw,
        final int access,
        final String name,
        final String desc,
        final String signature,
        final String[] exceptions,
        final boolean computeMaxs,
        final boolean computeFrames)
    {
        if (cw.firstMethod == null) {
            cw.firstMethod = this;
        } else {
            cw.lastMethod.next = this;
        }
        cw.lastMethod = this;
        this.cw = cw;
        this.access = access;
        this.name = cw.newUTF8(name);
        this.desc = cw.newUTF8(desc);
        this.descriptor = desc;
        if (ClassReader.SIGNATURES) {
            this.signature = signature;
        }
        if (exceptions != null && exceptions.length > 0) {
            exceptionCount = exceptions.length;
            this.exceptions = new int[exceptionCount];
            for (int i = 0; i < exceptionCount; ++i) {
                this.exceptions[i] = cw.newClass(exceptions[i]);
            }
        }
        this.compute = computeFrames ? FRAMES : (computeMaxs ? MAXS : NOTHING);
        if (computeMaxs || computeFrames) {
            if (computeFrames && "".equals(name)) {
                this.access |= ACC_CONSTRUCTOR;
            }
            // updates maxLocals
            int size = getArgumentsAndReturnSizes(descriptor) >> 2;
            if ((access & Opcodes.ACC_STATIC) != 0) {
                --size;
            }
            maxLocals = size;
            // creates and visits the label for the first basic block
            labels = new Label();
            labels.status |= Label.PUSHED;
            visitLabel(labels);
        }
    }

    // ------------------------------------------------------------------------
    // Implementation of the MethodVisitor interface
    // ------------------------------------------------------------------------

    /**
     * Computes the size of the arguments and of the return value of a method.
     *
     * @param desc the descriptor of a method.
     * @return the size of the arguments of the method (plus one for the
     *         implicit this argument), argSize, and the size of its return
     *         value, retSize, packed into a single int i =
     *         (argSize << 2) | retSize (argSize is therefore equal
     *         to i >> 2, and retSize to i & 0x03).
     */
    static int getArgumentsAndReturnSizes(final String desc) {
        int n = 1;
        int c = 1;
        while (true) {
            char car = desc.charAt(c++);
            if (car == ')') {
                car = desc.charAt(c);
                return n << 2
                        | (car == 'V' ? 0 : (car == 'D' || car == 'J' ? 2 : 1));
            } else if (car == 'L') {
                while (desc.charAt(c++) != ';') {
                }
                n += 1;
            } else if (car == '[') {
                while ((car = desc.charAt(c)) == '[') {
                    ++c;
                }
                if (car == 'D' || car == 'J') {
                    n -= 1;
                }
            } else if (car == 'D' || car == 'J') {
                n += 2;
            } else {
                n += 1;
            }
        }
    }

    /**
     * Reads an unsigned short value in the given byte array.
     *
     * @param b a byte array.
     * @param index the start index of the value to be read.
     * @return the read value.
     */
    static int readUnsignedShort(final byte[] b, final int index) {
        return ((b[index] & 0xFF) << 8) | (b[index + 1] & 0xFF);
    }

    /**
     * Reads a signed short value in the given byte array.
     *
     * @param b a byte array.
     * @param index the start index of the value to be read.
     * @return the read value.
     */
    static short readShort(final byte[] b, final int index) {
        return (short) (((b[index] & 0xFF) << 8) | (b[index + 1] & 0xFF));
    }

    /**
     * Reads a signed int value in the given byte array.
     *
     * @param b a byte array.
     * @param index the start index of the value to be read.
     * @return the read value.
     */
    static int readInt(final byte[] b, final int index) {
        return ((b[index] & 0xFF) << 24) | ((b[index + 1] & 0xFF) << 16)
                | ((b[index + 2] & 0xFF) << 8) | (b[index + 3] & 0xFF);
    }

    /**
     * Writes a short value in the given byte array.
     *
     * @param b a byte array.
     * @param index where the first byte of the short value must be written.
     * @param s the value to be written in the given byte array.
     */
    static void writeShort(final byte[] b, final int index, final int s) {
        b[index] = (byte) (s >>> 8);
        b[index + 1] = (byte) s;
    }

    /**
     * Computes the future value of a bytecode offset. 

Note: it is possible * to have several entries for the same instruction in the indexes * and sizes: two entries (index=a,size=b) and (index=a,size=b') * are equivalent to a single entry (index=a,size=b+b'). * * @param indexes current positions of the instructions to be resized. Each * instruction must be designated by the index of its last * byte, plus one (or, in other words, by the index of the first * byte of the next instruction). * @param sizes the number of bytes to be added to the above * instructions. More precisely, for each i < len, * sizes[i] bytes will be added at the end of the * instruction designated by indexes[i] or, if * sizes[i] is negative, the last |sizes[i]| * bytes of the instruction will be removed (the instruction size * must not become negative or null). * @param begin index of the first byte of the source instruction. * @param end index of the first byte of the target instruction. * @return the future value of the given bytecode offset. */ static int getNewOffset( final int[] indexes, final int[] sizes, final int begin, final int end) { int offset = end - begin; for (int i = 0; i < indexes.length; ++i) { if (begin < indexes[i] && indexes[i] <= end) { // forward jump offset += sizes[i]; } else if (end < indexes[i] && indexes[i] <= begin) { // backward jump offset -= sizes[i]; } } return offset; } /** * Updates the offset of the given label. * * @param indexes current positions of the instructions to be resized. Each * instruction must be designated by the index of its last * byte, plus one (or, in other words, by the index of the first * byte of the next instruction). * @param sizes the number of bytes to be added to the above * instructions. More precisely, for each i < len, * sizes[i] bytes will be added at the end of the * instruction designated by indexes[i] or, if * sizes[i] is negative, the last |sizes[i]| * bytes of the instruction will be removed (the instruction size * must not become negative or null). * @param label the label whose offset must be updated. */ static void getNewOffset( final int[] indexes, final int[] sizes, final Label label) { if ((label.status & Label.RESIZED) == 0) { label.position = getNewOffset(indexes, sizes, 0, label.position); label.status |= Label.RESIZED; } } public AnnotationVisitor visitAnnotationDefault() { if (!ClassReader.ANNOTATIONS) { return null; } annd = new ByteVector(); return new AnnotationWriter(cw, false, annd, null, 0); } public AnnotationVisitor visitAnnotation( final String desc, final boolean visible) { if (!ClassReader.ANNOTATIONS) { return null; } ByteVector bv = new ByteVector(); // write type, and reserve space for values count bv.putShort(cw.newUTF8(desc)).putShort(0); AnnotationWriter aw = new AnnotationWriter(cw, true, bv, bv, 2); if (visible) { aw.next = anns; anns = aw; } else { aw.next = ianns; ianns = aw; } return aw; } public AnnotationVisitor visitParameterAnnotation( final int parameter, final String desc, final boolean visible) { if (!ClassReader.ANNOTATIONS) { return null; } ByteVector bv = new ByteVector(); if ("Ljava/lang/Synthetic;".equals(desc)) { // workaround for a bug in javac with synthetic parameters // see ClassReader.readParameterAnnotations synthetics = Math.max(synthetics, parameter + 1); return new AnnotationWriter(cw, false, bv, null, 0); } // write type, and reserve space for values count bv.putShort(cw.newUTF8(desc)).putShort(0); AnnotationWriter aw = new AnnotationWriter(cw, true, bv, bv, 2); if (visible) { if (panns == null) { panns = new AnnotationWriter[Type.getArgumentTypes(descriptor).length]; } aw.next = panns[parameter]; panns[parameter] = aw; } else { if (ipanns == null) { ipanns = new AnnotationWriter[Type.getArgumentTypes(descriptor).length]; } aw.next = ipanns[parameter]; ipanns[parameter] = aw; } return aw; } public void visitAttribute(final Attribute attr) { if (attr.isCodeAttribute()) { attr.next = cattrs; cattrs = attr; } else { attr.next = attrs; attrs = attr; } } public void visitCode() { } public void visitFrame( final int type, final int nLocal, final Object[] local, final int nStack, final Object[] stack) { if (!ClassReader.FRAMES || compute == FRAMES) { return; } if (type == Opcodes.F_NEW) { startFrame(code.length, nLocal, nStack); for (int i = 0; i < nLocal; ++i) { if (local[i] instanceof String) { frame[frameIndex++] = Frame.OBJECT | cw.addType((String) local[i]); } else if (local[i] instanceof Integer) { frame[frameIndex++] = ((Integer) local[i]).intValue(); } else { frame[frameIndex++] = Frame.UNINITIALIZED | cw.addUninitializedType("", ((Label) local[i]).position); } } for (int i = 0; i < nStack; ++i) { if (stack[i] instanceof String) { frame[frameIndex++] = Frame.OBJECT | cw.addType((String) stack[i]); } else if (stack[i] instanceof Integer) { frame[frameIndex++] = ((Integer) stack[i]).intValue(); } else { frame[frameIndex++] = Frame.UNINITIALIZED | cw.addUninitializedType("", ((Label) stack[i]).position); } } endFrame(); } else { int delta; if (stackMap == null) { stackMap = new ByteVector(); delta = code.length; } else { delta = code.length - previousFrameOffset - 1; } switch (type) { case Opcodes.F_FULL: stackMap.putByte(FULL_FRAME) .putShort(delta) .putShort(nLocal); for (int i = 0; i < nLocal; ++i) { writeFrameType(local[i]); } stackMap.putShort(nStack); for (int i = 0; i < nStack; ++i) { writeFrameType(stack[i]); } break; case Opcodes.F_APPEND: stackMap.putByte(SAME_FRAME_EXTENDED + nLocal) .putShort(delta); for (int i = 0; i < nLocal; ++i) { writeFrameType(local[i]); } break; case Opcodes.F_CHOP: stackMap.putByte(SAME_FRAME_EXTENDED - nLocal) .putShort(delta); break; case Opcodes.F_SAME: if (delta < 64) { stackMap.putByte(delta); } else { stackMap.putByte(SAME_FRAME_EXTENDED).putShort(delta); } break; case Opcodes.F_SAME1: if (delta < 64) { stackMap.putByte(SAME_LOCALS_1_STACK_ITEM_FRAME + delta); } else { stackMap.putByte(SAME_LOCALS_1_STACK_ITEM_FRAME_EXTENDED) .putShort(delta); } writeFrameType(stack[0]); break; } previousFrameOffset = code.length; ++frameCount; } } public void visitInsn(final int opcode) { // adds the instruction to the bytecode of the method code.putByte(opcode); // update currentBlock // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, 0, null, null); } else { // updates current and max stack sizes int size = stackSize + Frame.SIZE[opcode]; if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } // if opcode == ATHROW or xRETURN, ends current block (no successor) if ((opcode >= Opcodes.IRETURN && opcode <= Opcodes.RETURN) || opcode == Opcodes.ATHROW) { noSuccessor(); } } } public void visitIntInsn(final int opcode, final int operand) { // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, operand, null, null); } else if (opcode != Opcodes.NEWARRAY) { // updates current and max stack sizes only for NEWARRAY // (stack size variation = 0 for BIPUSH or SIPUSH) int size = stackSize + 1; if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } } // adds the instruction to the bytecode of the method if (opcode == Opcodes.SIPUSH) { code.put12(opcode, operand); } else { // BIPUSH or NEWARRAY code.put11(opcode, operand); } } public void visitVarInsn(final int opcode, final int var) { // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, var, null, null); } else { // updates current and max stack sizes if (opcode == Opcodes.RET) { // no stack change, but end of current block (no successor) currentBlock.status |= Label.RET; // save 'stackSize' here for future use // (see {@link #findSubroutineSuccessors}) currentBlock.inputStackTop = stackSize; noSuccessor(); } else { // xLOAD or xSTORE int size = stackSize + Frame.SIZE[opcode]; if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } } } if (compute != NOTHING) { // updates max locals int n; if (opcode == Opcodes.LLOAD || opcode == Opcodes.DLOAD || opcode == Opcodes.LSTORE || opcode == Opcodes.DSTORE) { n = var + 2; } else { n = var + 1; } if (n > maxLocals) { maxLocals = n; } } // adds the instruction to the bytecode of the method if (var < 4 && opcode != Opcodes.RET) { int opt; if (opcode < Opcodes.ISTORE) { /* ILOAD_0 */ opt = 26 + ((opcode - Opcodes.ILOAD) << 2) + var; } else { /* ISTORE_0 */ opt = 59 + ((opcode - Opcodes.ISTORE) << 2) + var; } code.putByte(opt); } else if (var >= 256) { code.putByte(196 /* WIDE */).put12(opcode, var); } else { code.put11(opcode, var); } if (opcode >= Opcodes.ISTORE && compute == FRAMES && handlerCount > 0) { visitLabel(new Label()); } } public void visitTypeInsn(final int opcode, final String type) { Item i = cw.newClassItem(type); // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, code.length, cw, i); } else if (opcode == Opcodes.NEW) { // updates current and max stack sizes only if opcode == NEW // (no stack change for ANEWARRAY, CHECKCAST, INSTANCEOF) int size = stackSize + 1; if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } } // adds the instruction to the bytecode of the method code.put12(opcode, i.index); } public void visitFieldInsn( final int opcode, final String owner, final String name, final String desc) { Item i = cw.newFieldItem(owner, name, desc); // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, 0, cw, i); } else { int size; // computes the stack size variation char c = desc.charAt(0); switch (opcode) { case Opcodes.GETSTATIC: size = stackSize + (c == 'D' || c == 'J' ? 2 : 1); break; case Opcodes.PUTSTATIC: size = stackSize + (c == 'D' || c == 'J' ? -2 : -1); break; case Opcodes.GETFIELD: size = stackSize + (c == 'D' || c == 'J' ? 1 : 0); break; // case Constants.PUTFIELD: default: size = stackSize + (c == 'D' || c == 'J' ? -3 : -2); break; } // updates current and max stack sizes if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } } // adds the instruction to the bytecode of the method code.put12(opcode, i.index); } public void visitMethodInsn( final int opcode, final String owner, final String name, final String desc) { boolean itf = opcode == Opcodes.INVOKEINTERFACE; Item i = cw.newMethodItem(owner, name, desc, itf); int argSize = i.intVal; // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, 0, cw, i); } else { /* * computes the stack size variation. In order not to recompute * several times this variation for the same Item, we use the * intVal field of this item to store this variation, once it * has been computed. More precisely this intVal field stores * the sizes of the arguments and of the return value * corresponding to desc. */ if (argSize == 0) { // the above sizes have not been computed yet, // so we compute them... argSize = getArgumentsAndReturnSizes(desc); // ... and we save them in order // not to recompute them in the future i.intVal = argSize; } int size; if (opcode == Opcodes.INVOKESTATIC) { size = stackSize - (argSize >> 2) + (argSize & 0x03) + 1; } else { size = stackSize - (argSize >> 2) + (argSize & 0x03); } // updates current and max stack sizes if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } } // adds the instruction to the bytecode of the method if (itf) { if (argSize == 0) { argSize = getArgumentsAndReturnSizes(desc); i.intVal = argSize; } code.put12(Opcodes.INVOKEINTERFACE, i.index).put11(argSize >> 2, 0); } else { code.put12(opcode, i.index); } } public void visitJumpInsn(final int opcode, final Label label) { Label nextInsn = null; // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(opcode, 0, null, null); // 'label' is the target of a jump instruction label.getFirst().status |= Label.TARGET; // adds 'label' as a successor of this basic block addSuccessor(Edge.NORMAL, label); if (opcode != Opcodes.GOTO) { // creates a Label for the next basic block nextInsn = new Label(); } } else { if (opcode == Opcodes.JSR) { if ((label.status & Label.SUBROUTINE) == 0) { label.status |= Label.SUBROUTINE; ++subroutines; } currentBlock.status |= Label.JSR; addSuccessor(stackSize + 1, label); // creates a Label for the next basic block nextInsn = new Label(); /* * note that, by construction in this method, a JSR block * has at least two successors in the control flow graph: * the first one leads the next instruction after the JSR, * while the second one leads to the JSR target. */ } else { // updates current stack size (max stack size unchanged // because stack size variation always negative in this // case) stackSize += Frame.SIZE[opcode]; addSuccessor(stackSize, label); } } } // adds the instruction to the bytecode of the method if ((label.status & Label.RESOLVED) != 0 && label.position - code.length < Short.MIN_VALUE) { /* * case of a backward jump with an offset < -32768. In this case we * automatically replace GOTO with GOTO_W, JSR with JSR_W and IFxxx * with IFNOTxxx GOTO_W , where IFNOTxxx is the * "opposite" opcode of IFxxx (i.e., IFNE for IFEQ) and where * designates the instruction just after the GOTO_W. */ if (opcode == Opcodes.GOTO) { code.putByte(200); // GOTO_W } else if (opcode == Opcodes.JSR) { code.putByte(201); // JSR_W } else { // if the IF instruction is transformed into IFNOT GOTO_W the // next instruction becomes the target of the IFNOT instruction if (nextInsn != null) { nextInsn.status |= Label.TARGET; } code.putByte(opcode <= 166 ? ((opcode + 1) ^ 1) - 1 : opcode ^ 1); code.putShort(8); // jump offset code.putByte(200); // GOTO_W } label.put(this, code, code.length - 1, true); } else { /* * case of a backward jump with an offset >= -32768, or of a forward * jump with, of course, an unknown offset. In these cases we store * the offset in 2 bytes (which will be increased in * resizeInstructions, if needed). */ code.putByte(opcode); label.put(this, code, code.length - 1, false); } if (currentBlock != null) { if (nextInsn != null) { // if the jump instruction is not a GOTO, the next instruction // is also a successor of this instruction. Calling visitLabel // adds the label of this next instruction as a successor of the // current block, and starts a new basic block visitLabel(nextInsn); } if (opcode == Opcodes.GOTO) { noSuccessor(); } } } public void visitLabel(final Label label) { // resolves previous forward references to label, if any resize |= label.resolve(this, code.length, code.data); // updates currentBlock if ((label.status & Label.DEBUG) != 0) { return; } if (compute == FRAMES) { if (currentBlock != null) { if (label.position == currentBlock.position) { // successive labels, do not start a new basic block currentBlock.status |= (label.status & Label.TARGET); label.frame = currentBlock.frame; return; } // ends current block (with one new successor) addSuccessor(Edge.NORMAL, label); } // begins a new current block currentBlock = label; if (label.frame == null) { label.frame = new Frame(); label.frame.owner = label; } // updates the basic block list if (previousBlock != null) { if (label.position == previousBlock.position) { previousBlock.status |= (label.status & Label.TARGET); label.frame = previousBlock.frame; currentBlock = previousBlock; return; } previousBlock.successor = label; } previousBlock = label; } else if (compute == MAXS) { if (currentBlock != null) { // ends current block (with one new successor) currentBlock.outputStackMax = maxStackSize; addSuccessor(stackSize, label); } // begins a new current block currentBlock = label; // resets the relative current and max stack sizes stackSize = 0; maxStackSize = 0; // updates the basic block list if (previousBlock != null) { previousBlock.successor = label; } previousBlock = label; } } public void visitLdcInsn(final Object cst) { Item i = cw.newConstItem(cst); // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(Opcodes.LDC, 0, cw, i); } else { int size; // computes the stack size variation if (i.type == ClassWriter.LONG || i.type == ClassWriter.DOUBLE) { size = stackSize + 2; } else { size = stackSize + 1; } // updates current and max stack sizes if (size > maxStackSize) { maxStackSize = size; } stackSize = size; } } // adds the instruction to the bytecode of the method int index = i.index; if (i.type == ClassWriter.LONG || i.type == ClassWriter.DOUBLE) { code.put12(20 /* LDC2_W */, index); } else if (index >= 256) { code.put12(19 /* LDC_W */, index); } else { code.put11(Opcodes.LDC, index); } } public void visitIincInsn(final int var, final int increment) { if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(Opcodes.IINC, var, null, null); } } if (compute != NOTHING) { // updates max locals int n = var + 1; if (n > maxLocals) { maxLocals = n; } } // adds the instruction to the bytecode of the method if ((var > 255) || (increment > 127) || (increment < -128)) { code.putByte(196 /* WIDE */) .put12(Opcodes.IINC, var) .putShort(increment); } else { code.putByte(Opcodes.IINC).put11(var, increment); } } public void visitTableSwitchInsn( final int min, final int max, final Label dflt, final Label[] labels) { // adds the instruction to the bytecode of the method int source = code.length; code.putByte(Opcodes.TABLESWITCH); code.length += (4 - code.length % 4) % 4; dflt.put(this, code, source, true); code.putInt(min).putInt(max); for (int i = 0; i < labels.length; ++i) { labels[i].put(this, code, source, true); } // updates currentBlock visitSwitchInsn(dflt, labels); } public void visitLookupSwitchInsn( final Label dflt, final int[] keys, final Label[] labels) { // adds the instruction to the bytecode of the method int source = code.length; code.putByte(Opcodes.LOOKUPSWITCH); code.length += (4 - code.length % 4) % 4; dflt.put(this, code, source, true); code.putInt(labels.length); for (int i = 0; i < labels.length; ++i) { code.putInt(keys[i]); labels[i].put(this, code, source, true); } // updates currentBlock visitSwitchInsn(dflt, labels); } // ------------------------------------------------------------------------ // Utility methods: control flow analysis algorithm // ------------------------------------------------------------------------ private void visitSwitchInsn(final Label dflt, final Label[] labels) { // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(Opcodes.LOOKUPSWITCH, 0, null, null); // adds current block successors addSuccessor(Edge.NORMAL, dflt); dflt.getFirst().status |= Label.TARGET; for (int i = 0; i < labels.length; ++i) { addSuccessor(Edge.NORMAL, labels[i]); labels[i].getFirst().status |= Label.TARGET; } } else { // updates current stack size (max stack size unchanged) --stackSize; // adds current block successors addSuccessor(stackSize, dflt); for (int i = 0; i < labels.length; ++i) { addSuccessor(stackSize, labels[i]); } } // ends current block noSuccessor(); } } public void visitMultiANewArrayInsn(final String desc, final int dims) { Item i = cw.newClassItem(desc); // Label currentBlock = this.currentBlock; if (currentBlock != null) { if (compute == FRAMES) { currentBlock.frame.execute(Opcodes.MULTIANEWARRAY, dims, cw, i); } else { // updates current stack size (max stack size unchanged because // stack size variation always negative or null) stackSize += 1 - dims; } } // adds the instruction to the bytecode of the method code.put12(Opcodes.MULTIANEWARRAY, i.index).putByte(dims); } public void visitTryCatchBlock( final Label start, final Label end, final Label handler, final String type) { ++handlerCount; Handler h = new Handler(); h.start = start; h.end = end; h.handler = handler; h.desc = type; h.type = type != null ? cw.newClass(type) : 0; if (lastHandler == null) { firstHandler = h; } else { lastHandler.next = h; } lastHandler = h; } // ------------------------------------------------------------------------ // Utility methods: stack map frames // ------------------------------------------------------------------------ public void visitLocalVariable( final String name, final String desc, final String signature, final Label start, final Label end, final int index) { if (signature != null) { if (localVarType == null) { localVarType = new ByteVector(); } ++localVarTypeCount; localVarType.putShort(start.position) .putShort(end.position - start.position) .putShort(cw.newUTF8(name)) .putShort(cw.newUTF8(signature)) .putShort(index); } if (localVar == null) { localVar = new ByteVector(); } ++localVarCount; localVar.putShort(start.position) .putShort(end.position - start.position) .putShort(cw.newUTF8(name)) .putShort(cw.newUTF8(desc)) .putShort(index); if (compute != NOTHING) { // updates max locals char c = desc.charAt(0); int n = index + (c == 'J' || c == 'D' ? 2 : 1); if (n > maxLocals) { maxLocals = n; } } } public void visitLineNumber(final int line, final Label start) { if (lineNumber == null) { lineNumber = new ByteVector(); } ++lineNumberCount; lineNumber.putShort(start.position); lineNumber.putShort(line); } public void visitMaxs(final int maxStack, final int maxLocals) { if (ClassReader.FRAMES && compute == FRAMES) { // completes the control flow graph with exception handler blocks Handler handler = firstHandler; while (handler != null) { Label l = handler.start.getFirst(); Label h = handler.handler.getFirst(); Label e = handler.end.getFirst(); // computes the kind of the edges to 'h' String t = handler.desc == null ? "java/lang/Throwable" : handler.desc; int kind = Frame.OBJECT | cw.addType(t); // h is an exception handler h.status |= Label.TARGET; // adds 'h' as a successor of labels between 'start' and 'end' while (l != e) { // creates an edge to 'h' Edge b = new Edge(); b.info = kind; b.successor = h; // adds it to the successors of 'l' b.next = l.successors; l.successors = b; // goes to the next label l = l.successor; } handler = handler.next; } // creates and visits the first (implicit) frame Frame f = labels.frame; Type[] args = Type.getArgumentTypes(descriptor); f.initInputFrame(cw, access, args, this.maxLocals); visitFrame(f); /* * fix point algorithm: mark the first basic block as 'changed' * (i.e. put it in the 'changed' list) and, while there are changed * basic blocks, choose one, mark it as unchanged, and update its * successors (which can be changed in the process). */ int max = 0; Label changed = labels; while (changed != null) { // removes a basic block from the list of changed basic blocks Label l = changed; changed = changed.next; l.next = null; f = l.frame; // a reacheable jump target must be stored in the stack map if ((l.status & Label.TARGET) != 0) { l.status |= Label.STORE; } // all visited labels are reacheable, by definition l.status |= Label.REACHABLE; // updates the (absolute) maximum stack size int blockMax = f.inputStack.length + l.outputStackMax; if (blockMax > max) { max = blockMax; } // updates the successors of the current basic block Edge e = l.successors; while (e != null) { Label n = e.successor.getFirst(); boolean change = f.merge(cw, n.frame, e.info); if (change && n.next == null) { // if n has changed and is not already in the 'changed' // list, adds it to this list n.next = changed; changed = n; } e = e.next; } } this.maxStack = max; // visits all the frames that must be stored in the stack map Label l = labels; while (l != null) { f = l.frame; if ((l.status & Label.STORE) != 0) { visitFrame(f); } if ((l.status & Label.REACHABLE) == 0) { // finds start and end of dead basic block Label k = l.successor; int start = l.position; int end = (k == null ? code.length : k.position) - 1; // if non empty basic block if (end >= start) { // replaces instructions with NOP ... NOP ATHROW for (int i = start; i < end; ++i) { code.data[i] = Opcodes.NOP; } code.data[end] = (byte) Opcodes.ATHROW; // emits a frame for this unreachable block startFrame(start, 0, 1); frame[frameIndex++] = Frame.OBJECT | cw.addType("java/lang/Throwable"); endFrame(); } } l = l.successor; } } else if (compute == MAXS) { // completes the control flow graph with exception handler blocks Handler handler = firstHandler; while (handler != null) { Label l = handler.start; Label h = handler.handler; Label e = handler.end; // adds 'h' as a successor of labels between 'start' and 'end' while (l != e) { // creates an edge to 'h' Edge b = new Edge(); b.info = Edge.EXCEPTION; b.successor = h; // adds it to the successors of 'l' if ((l.status & Label.JSR) == 0) { b.next = l.successors; l.successors = b; } else { // if l is a JSR block, adds b after the first two edges // to preserve the hypothesis about JSR block successors // order (see {@link #visitJumpInsn}) b.next = l.successors.next.next; l.successors.next.next = b; } // goes to the next label l = l.successor; } handler = handler.next; } if (subroutines > 0) { // completes the control flow graph with the RET successors /* * first step: finds the subroutines. This step determines, for * each basic block, to which subroutine(s) it belongs. */ // finds the basic blocks that belong to the "main" subroutine int id = 0; labels.visitSubroutine(null, 1, subroutines); // finds the basic blocks that belong to the real subroutines Label l = labels; while (l != null) { if ((l.status & Label.JSR) != 0) { // the subroutine is defined by l's TARGET, not by l Label subroutine = l.successors.next.successor; // if this subroutine has not been visited yet... if ((subroutine.status & Label.VISITED) == 0) { // ...assigns it a new id and finds its basic blocks id += 1; subroutine.visitSubroutine(null, (id / 32L) << 32 | (1L << (id % 32)), subroutines); } } l = l.successor; } // second step: finds the successors of RET blocks l = labels; while (l != null) { if ((l.status & Label.JSR) != 0) { Label L = labels; while (L != null) { L.status &= ~Label.VISITED; L = L.successor; } // the subroutine is defined by l's TARGET, not by l Label subroutine = l.successors.next.successor; subroutine.visitSubroutine(l, 0, subroutines); } l = l.successor; } } /* * control flow analysis algorithm: while the block stack is not * empty, pop a block from this stack, update the max stack size, * compute the true (non relative) begin stack size of the * successors of this block, and push these successors onto the * stack (unless they have already been pushed onto the stack). * Note: by hypothesis, the {@link Label#inputStackTop} of the * blocks in the block stack are the true (non relative) beginning * stack sizes of these blocks. */ int max = 0; Label stack = labels; while (stack != null) { // pops a block from the stack Label l = stack; stack = stack.next; // computes the true (non relative) max stack size of this block int start = l.inputStackTop; int blockMax = start + l.outputStackMax; // updates the global max stack size if (blockMax > max) { max = blockMax; } // analyzes the successors of the block Edge b = l.successors; if ((l.status & Label.JSR) != 0) { // ignores the first edge of JSR blocks (virtual successor) b = b.next; } while (b != null) { l = b.successor; // if this successor has not already been pushed... if ((l.status & Label.PUSHED) == 0) { // computes its true beginning stack size... l.inputStackTop = b.info == Edge.EXCEPTION ? 1 : start + b.info; // ...and pushes it onto the stack l.status |= Label.PUSHED; l.next = stack; stack = l; } b = b.next; } } this.maxStack = max; } else { this.maxStack = maxStack; this.maxLocals = maxLocals; } } public void visitEnd() { } /** * Adds a successor to the {@link #currentBlock currentBlock} block. * * @param info information about the control flow edge to be added. * @param successor the successor block to be added to the current block. */ private void addSuccessor(final int info, final Label successor) { // creates and initializes an Edge object... Edge b = new Edge(); b.info = info; b.successor = successor; // ...and adds it to the successor list of the currentBlock block b.next = currentBlock.successors; currentBlock.successors = b; } /** * Ends the current basic block. This method must be used in the case where * the current basic block does not have any successor. */ private void noSuccessor() { if (compute == FRAMES) { Label l = new Label(); l.frame = new Frame(); l.frame.owner = l; l.resolve(this, code.length, code.data); previousBlock.successor = l; previousBlock = l; } else { currentBlock.outputStackMax = maxStackSize; } currentBlock = null; } // ------------------------------------------------------------------------ // Utility methods: dump bytecode array // ------------------------------------------------------------------------ /** * Visits a frame that has been computed from scratch. * * @param f the frame that must be visited. */ private void visitFrame(final Frame f) { int i, t; int nTop = 0; int nLocal = 0; int nStack = 0; int[] locals = f.inputLocals; int[] stacks = f.inputStack; // computes the number of locals (ignores TOP types that are just after // a LONG or a DOUBLE, and all trailing TOP types) for (i = 0; i < locals.length; ++i) { t = locals[i]; if (t == Frame.TOP) { ++nTop; } else { nLocal += nTop + 1; nTop = 0; } if (t == Frame.LONG || t == Frame.DOUBLE) { ++i; } } // computes the stack size (ignores TOP types that are just after // a LONG or a DOUBLE) for (i = 0; i < stacks.length; ++i) { t = stacks[i]; ++nStack; if (t == Frame.LONG || t == Frame.DOUBLE) { ++i; } } // visits the frame and its content startFrame(f.owner.position, nLocal, nStack); for (i = 0; nLocal > 0; ++i, --nLocal) { t = locals[i]; frame[frameIndex++] = t; if (t == Frame.LONG || t == Frame.DOUBLE) { ++i; } } for (i = 0; i < stacks.length; ++i) { t = stacks[i]; frame[frameIndex++] = t; if (t == Frame.LONG || t == Frame.DOUBLE) { ++i; } } endFrame(); } /** * Starts the visit of a stack map frame. * * @param offset the offset of the instruction to which the frame * corresponds. * @param nLocal the number of local variables in the frame. * @param nStack the number of stack elements in the frame. */ private void startFrame(final int offset, final int nLocal, final int nStack) { int n = 3 + nLocal + nStack; if (frame == null || frame.length < n) { frame = new int[n]; } frame[0] = offset; frame[1] = nLocal; frame[2] = nStack; frameIndex = 3; } // ------------------------------------------------------------------------ // Utility methods: instruction resizing (used to handle GOTO_W and JSR_W) // ------------------------------------------------------------------------ /** * Checks if the visit of the current frame {@link #frame} is finished, and * if yes, write it in the StackMapTable attribute. */ private void endFrame() { if (previousFrame != null) { // do not write the first frame if (stackMap == null) { stackMap = new ByteVector(); } writeFrame(); ++frameCount; } previousFrame = frame; frame = null; } /** * Compress and writes the current frame {@link #frame} in the StackMapTable * attribute. */ private void writeFrame() { int clocalsSize = frame[1]; int cstackSize = frame[2]; if ((cw.version & 0xFFFF) < Opcodes.V1_6) { stackMap.putShort(frame[0]).putShort(clocalsSize); writeFrameTypes(3, 3 + clocalsSize); stackMap.putShort(cstackSize); writeFrameTypes(3 + clocalsSize, 3 + clocalsSize + cstackSize); return; } int localsSize = previousFrame[1]; int type = FULL_FRAME; int k = 0; int delta; if (frameCount == 0) { delta = frame[0]; } else { delta = frame[0] - previousFrame[0] - 1; } if (cstackSize == 0) { k = clocalsSize - localsSize; switch (k) { case -3: case -2: case -1: type = CHOP_FRAME; localsSize = clocalsSize; break; case 0: type = delta < 64 ? SAME_FRAME : SAME_FRAME_EXTENDED; break; case 1: case 2: case 3: type = APPEND_FRAME; break; } } else if (clocalsSize == localsSize && cstackSize == 1) { type = delta < 63 ? SAME_LOCALS_1_STACK_ITEM_FRAME : SAME_LOCALS_1_STACK_ITEM_FRAME_EXTENDED; } if (type != FULL_FRAME) { // verify if locals are the same int l = 3; for (int j = 0; j < localsSize; j++) { if (frame[l] != previousFrame[l]) { type = FULL_FRAME; break; } l++; } } switch (type) { case SAME_FRAME: stackMap.putByte(delta); break; case SAME_LOCALS_1_STACK_ITEM_FRAME: stackMap.putByte(SAME_LOCALS_1_STACK_ITEM_FRAME + delta); writeFrameTypes(3 + clocalsSize, 4 + clocalsSize); break; case SAME_LOCALS_1_STACK_ITEM_FRAME_EXTENDED: stackMap.putByte(SAME_LOCALS_1_STACK_ITEM_FRAME_EXTENDED) .putShort(delta); writeFrameTypes(3 + clocalsSize, 4 + clocalsSize); break; case SAME_FRAME_EXTENDED: stackMap.putByte(SAME_FRAME_EXTENDED).putShort(delta); break; case CHOP_FRAME: stackMap.putByte(SAME_FRAME_EXTENDED + k).putShort(delta); break; case APPEND_FRAME: stackMap.putByte(SAME_FRAME_EXTENDED + k).putShort(delta); writeFrameTypes(3 + localsSize, 3 + clocalsSize); break; // case FULL_FRAME: default: stackMap.putByte(FULL_FRAME) .putShort(delta) .putShort(clocalsSize); writeFrameTypes(3, 3 + clocalsSize); stackMap.putShort(cstackSize); writeFrameTypes(3 + clocalsSize, 3 + clocalsSize + cstackSize); } } /** * Writes some types of the current frame {@link #frame} into the * StackMapTableAttribute. This method converts types from the format used * in {@link Label} to the format used in StackMapTable attributes. In * particular, it converts type table indexes to constant pool indexes. * * @param start index of the first type in {@link #frame} to write. * @param end index of last type in {@link #frame} to write (exclusive). */ private void writeFrameTypes(final int start, final int end) { for (int i = start; i < end; ++i) { int t = frame[i]; int d = t & Frame.DIM; if (d == 0) { int v = t & Frame.BASE_VALUE; switch (t & Frame.BASE_KIND) { case Frame.OBJECT: stackMap.putByte(7) .putShort(cw.newClass(cw.typeTable[v].strVal1)); break; case Frame.UNINITIALIZED: stackMap.putByte(8).putShort(cw.typeTable[v].intVal); break; default: stackMap.putByte(v); } } else { StringBuilder buf = new StringBuilder(); d >>= 28; while (d-- > 0) { buf.append('['); } if ((t & Frame.BASE_KIND) == Frame.OBJECT) { buf.append('L'); buf.append(cw.typeTable[t & Frame.BASE_VALUE].strVal1); buf.append(';'); } else { switch (t & 0xF) { case 1: buf.append('I'); break; case 2: buf.append('F'); break; case 3: buf.append('D'); break; case 9: buf.append('Z'); break; case 10: buf.append('B'); break; case 11: buf.append('C'); break; case 12: buf.append('S'); break; default: buf.append('J'); } } stackMap.putByte(7).putShort(cw.newClass(buf.toString())); } } } private void writeFrameType(final Object type) { if (type instanceof String) { stackMap.putByte(7).putShort(cw.newClass((String) type)); } else if (type instanceof Integer) { stackMap.putByte(((Integer) type).intValue()); } else { stackMap.putByte(8).putShort(((Label) type).position); } } /** * Returns the size of the bytecode of this method. * * @return the size of the bytecode of this method. */ final int getSize() { if (classReaderOffset != 0) { return 6 + classReaderLength; } if (resize) { // replaces the temporary jump opcodes introduced by Label.resolve. if (ClassReader.RESIZE) { resizeInstructions(); } else { throw new RuntimeException("Method code too large!"); } } int size = 8; if (code.length > 0) { cw.newUTF8("Code"); size += 18 + code.length + 8 * handlerCount; if (localVar != null) { cw.newUTF8("LocalVariableTable"); size += 8 + localVar.length; } if (localVarType != null) { cw.newUTF8("LocalVariableTypeTable"); size += 8 + localVarType.length; } if (lineNumber != null) { cw.newUTF8("LineNumberTable"); size += 8 + lineNumber.length; } if (stackMap != null) { boolean zip = (cw.version & 0xFFFF) >= Opcodes.V1_6; cw.newUTF8(zip ? "StackMapTable" : "StackMap"); size += 8 + stackMap.length; } if (cattrs != null) { size += cattrs.getSize(cw, code.data, code.length, maxStack, maxLocals); } } if (exceptionCount > 0) { cw.newUTF8("Exceptions"); size += 8 + 2 * exceptionCount; } if ((access & Opcodes.ACC_SYNTHETIC) != 0 && (cw.version & 0xffff) < Opcodes.V1_5) { cw.newUTF8("Synthetic"); size += 6; } if ((access & Opcodes.ACC_DEPRECATED) != 0) { cw.newUTF8("Deprecated"); size += 6; } if (ClassReader.SIGNATURES && signature != null) { cw.newUTF8("Signature"); cw.newUTF8(signature); size += 8; } if (ClassReader.ANNOTATIONS && annd != null) { cw.newUTF8("AnnotationDefault"); size += 6 + annd.length; } if (ClassReader.ANNOTATIONS && anns != null) { cw.newUTF8("RuntimeVisibleAnnotations"); size += 8 + anns.getSize(); } if (ClassReader.ANNOTATIONS && ianns != null) { cw.newUTF8("RuntimeInvisibleAnnotations"); size += 8 + ianns.getSize(); } if (ClassReader.ANNOTATIONS && panns != null) { cw.newUTF8("RuntimeVisibleParameterAnnotations"); size += 7 + 2 * (panns.length - synthetics); for (int i = panns.length - 1; i >= synthetics; --i) { size += panns[i] == null ? 0 : panns[i].getSize(); } } if (ClassReader.ANNOTATIONS && ipanns != null) { cw.newUTF8("RuntimeInvisibleParameterAnnotations"); size += 7 + 2 * (ipanns.length - synthetics); for (int i = ipanns.length - 1; i >= synthetics; --i) { size += ipanns[i] == null ? 0 : ipanns[i].getSize(); } } if (attrs != null) { size += attrs.getSize(cw, null, 0, -1, -1); } return size; } /** * Puts the bytecode of this method in the given byte vector. * * @param out the byte vector into which the bytecode of this method must be * copied. */ final void put(final ByteVector out) { out.putShort(access).putShort(name).putShort(desc); if (classReaderOffset != 0) { out.putByteArray(cw.cr.b, classReaderOffset, classReaderLength); return; } int attributeCount = 0; if (code.length > 0) { ++attributeCount; } if (exceptionCount > 0) { ++attributeCount; } if ((access & Opcodes.ACC_SYNTHETIC) != 0 && (cw.version & 0xffff) < Opcodes.V1_5) { ++attributeCount; } if ((access & Opcodes.ACC_DEPRECATED) != 0) { ++attributeCount; } if (ClassReader.SIGNATURES && signature != null) { ++attributeCount; } if (ClassReader.ANNOTATIONS && annd != null) { ++attributeCount; } if (ClassReader.ANNOTATIONS && anns != null) { ++attributeCount; } if (ClassReader.ANNOTATIONS && ianns != null) { ++attributeCount; } if (ClassReader.ANNOTATIONS && panns != null) { ++attributeCount; } if (ClassReader.ANNOTATIONS && ipanns != null) { ++attributeCount; } if (attrs != null) { attributeCount += attrs.getCount(); } out.putShort(attributeCount); if (code.length > 0) { int size = 12 + code.length + 8 * handlerCount; if (localVar != null) { size += 8 + localVar.length; } if (localVarType != null) { size += 8 + localVarType.length; } if (lineNumber != null) { size += 8 + lineNumber.length; } if (stackMap != null) { size += 8 + stackMap.length; } if (cattrs != null) { size += cattrs.getSize(cw, code.data, code.length, maxStack, maxLocals); } out.putShort(cw.newUTF8("Code")).putInt(size); out.putShort(maxStack).putShort(maxLocals); out.putInt(code.length).putByteArray(code.data, 0, code.length); out.putShort(handlerCount); if (handlerCount > 0) { Handler h = firstHandler; while (h != null) { out.putShort(h.start.position) .putShort(h.end.position) .putShort(h.handler.position) .putShort(h.type); h = h.next; } } attributeCount = 0; if (localVar != null) { ++attributeCount; } if (localVarType != null) { ++attributeCount; } if (lineNumber != null) { ++attributeCount; } if (stackMap != null) { ++attributeCount; } if (cattrs != null) { attributeCount += cattrs.getCount(); } out.putShort(attributeCount); if (localVar != null) { out.putShort(cw.newUTF8("LocalVariableTable")); out.putInt(localVar.length + 2).putShort(localVarCount); out.putByteArray(localVar.data, 0, localVar.length); } if (localVarType != null) { out.putShort(cw.newUTF8("LocalVariableTypeTable")); out.putInt(localVarType.length + 2).putShort(localVarTypeCount); out.putByteArray(localVarType.data, 0, localVarType.length); } if (lineNumber != null) { out.putShort(cw.newUTF8("LineNumberTable")); out.putInt(lineNumber.length + 2).putShort(lineNumberCount); out.putByteArray(lineNumber.data, 0, lineNumber.length); } if (stackMap != null) { boolean zip = (cw.version & 0xFFFF) >= Opcodes.V1_6; out.putShort(cw.newUTF8(zip ? "StackMapTable" : "StackMap")); out.putInt(stackMap.length + 2).putShort(frameCount); out.putByteArray(stackMap.data, 0, stackMap.length); } if (cattrs != null) { cattrs.put(cw, code.data, code.length, maxLocals, maxStack, out); } } if (exceptionCount > 0) { out.putShort(cw.newUTF8("Exceptions")) .putInt(2 * exceptionCount + 2); out.putShort(exceptionCount); for (int i = 0; i < exceptionCount; ++i) { out.putShort(exceptions[i]); } } if ((access & Opcodes.ACC_SYNTHETIC) != 0 && (cw.version & 0xffff) < Opcodes.V1_5) { out.putShort(cw.newUTF8("Synthetic")).putInt(0); } if ((access & Opcodes.ACC_DEPRECATED) != 0) { out.putShort(cw.newUTF8("Deprecated")).putInt(0); } if (ClassReader.SIGNATURES && signature != null) { out.putShort(cw.newUTF8("Signature")) .putInt(2) .putShort(cw.newUTF8(signature)); } if (ClassReader.ANNOTATIONS && annd != null) { out.putShort(cw.newUTF8("AnnotationDefault")); out.putInt(annd.length); out.putByteArray(annd.data, 0, annd.length); } if (ClassReader.ANNOTATIONS && anns != null) { out.putShort(cw.newUTF8("RuntimeVisibleAnnotations")); anns.put(out); } if (ClassReader.ANNOTATIONS && ianns != null) { out.putShort(cw.newUTF8("RuntimeInvisibleAnnotations")); ianns.put(out); } if (ClassReader.ANNOTATIONS && panns != null) { out.putShort(cw.newUTF8("RuntimeVisibleParameterAnnotations")); AnnotationWriter.put(panns, synthetics, out); } if (ClassReader.ANNOTATIONS && ipanns != null) { out.putShort(cw.newUTF8("RuntimeInvisibleParameterAnnotations")); AnnotationWriter.put(ipanns, synthetics, out); } if (attrs != null) { attrs.put(cw, null, 0, -1, -1, out); } } /** * Resizes and replaces the temporary instructions inserted by * {@link Label#resolve} for wide forward jumps, while keeping jump offsets * and instruction addresses consistent. This may require to resize other * existing instructions, or even to introduce new instructions: for * example, increasing the size of an instruction by 2 at the middle of a * method can increases the offset of an IFEQ instruction from 32766 to * 32768, in which case IFEQ 32766 must be replaced with IFNEQ 8 GOTO_W * 32765. This, in turn, may require to increase the size of another jump * instruction, and so on... All these operations are handled automatically * by this method.

This method must be called after all the method * that is being built has been visited. In particular, the * {@link Label Label} objects used to construct the method are no longer * valid after this method has been called. */ private void resizeInstructions() { byte[] b = code.data; // bytecode of the method int u, v, label; // indexes in b int i, j; // loop indexes /* * 1st step: As explained above, resizing an instruction may require to * resize another one, which may require to resize yet another one, and * so on. The first step of the algorithm consists in finding all the * instructions that need to be resized, without modifying the code. * This is done by the following "fix point" algorithm: * * Parse the code to find the jump instructions whose offset will need * more than 2 bytes to be stored (the future offset is computed from * the current offset and from the number of bytes that will be inserted * or removed between the source and target instructions). For each such * instruction, adds an entry in (a copy of) the indexes and sizes * arrays (if this has not already been done in a previous iteration!). * * If at least one entry has been added during the previous step, go * back to the beginning, otherwise stop. * * In fact the real algorithm is complicated by the fact that the size * of TABLESWITCH and LOOKUPSWITCH instructions depends on their * position in the bytecode (because of padding). In order to ensure the * convergence of the algorithm, the number of bytes to be added or * removed from these instructions is over estimated during the previous * loop, and computed exactly only after the loop is finished (this * requires another pass to parse the bytecode of the method). */ int[] allIndexes = new int[0]; // copy of indexes int[] allSizes = new int[0]; // copy of sizes boolean[] resize; // instructions to be resized int newOffset; // future offset of a jump instruction resize = new boolean[code.length]; // 3 = loop again, 2 = loop ended, 1 = last pass, 0 = done int state = 3; do { if (state == 3) { state = 2; } u = 0; while (u < b.length) { int opcode = b[u] & 0xFF; // opcode of current instruction int insert = 0; // bytes to be added after this instruction switch (ClassWriter.TYPE[opcode]) { case ClassWriter.NOARG_INSN: case ClassWriter.IMPLVAR_INSN: u += 1; break; case ClassWriter.LABEL_INSN: if (opcode > 201) { // converts temporary opcodes 202 to 217, 218 and // 219 to IFEQ ... JSR (inclusive), IFNULL and // IFNONNULL opcode = opcode < 218 ? opcode - 49 : opcode - 20; label = u + readUnsignedShort(b, u + 1); } else { label = u + readShort(b, u + 1); } newOffset = getNewOffset(allIndexes, allSizes, u, label); if (newOffset < Short.MIN_VALUE || newOffset > Short.MAX_VALUE) { if (!resize[u]) { if (opcode == Opcodes.GOTO || opcode == Opcodes.JSR) { // two additional bytes will be required to // replace this GOTO or JSR instruction with // a GOTO_W or a JSR_W insert = 2; } else { // five additional bytes will be required to // replace this IFxxx instruction with // IFNOTxxx GOTO_W , where IFNOTxxx // is the "opposite" opcode of IFxxx (i.e., // IFNE for IFEQ) and where designates // the instruction just after the GOTO_W. insert = 5; } resize[u] = true; } } u += 3; break; case ClassWriter.LABELW_INSN: u += 5; break; case ClassWriter.TABL_INSN: if (state == 1) { // true number of bytes to be added (or removed) // from this instruction = (future number of padding // bytes - current number of padding byte) - // previously over estimated variation = // = ((3 - newOffset%4) - (3 - u%4)) - u%4 // = (-newOffset%4 + u%4) - u%4 // = -(newOffset & 3) newOffset = getNewOffset(allIndexes, allSizes, 0, u); insert = -(newOffset & 3); } else if (!resize[u]) { // over estimation of the number of bytes to be // added to this instruction = 3 - current number // of padding bytes = 3 - (3 - u%4) = u%4 = u & 3 insert = u & 3; resize[u] = true; } // skips instruction u = u + 4 - (u & 3); u += 4 * (readInt(b, u + 8) - readInt(b, u + 4) + 1) + 12; break; case ClassWriter.LOOK_INSN: if (state == 1) { // like TABL_INSN newOffset = getNewOffset(allIndexes, allSizes, 0, u); insert = -(newOffset & 3); } else if (!resize[u]) { // like TABL_INSN insert = u & 3; resize[u] = true; } // skips instruction u = u + 4 - (u & 3); u += 8 * readInt(b, u + 4) + 8; break; case ClassWriter.WIDE_INSN: opcode = b[u + 1] & 0xFF; if (opcode == Opcodes.IINC) { u += 6; } else { u += 4; } break; case ClassWriter.VAR_INSN: case ClassWriter.SBYTE_INSN: case ClassWriter.LDC_INSN: u += 2; break; case ClassWriter.SHORT_INSN: case ClassWriter.LDCW_INSN: case ClassWriter.FIELDORMETH_INSN: case ClassWriter.TYPE_INSN: case ClassWriter.IINC_INSN: u += 3; break; case ClassWriter.ITFMETH_INSN: u += 5; break; // case ClassWriter.MANA_INSN: default: u += 4; break; } if (insert != 0) { // adds a new (u, insert) entry in the allIndexes and // allSizes arrays int[] newIndexes = new int[allIndexes.length + 1]; int[] newSizes = new int[allSizes.length + 1]; System.arraycopy(allIndexes, 0, newIndexes, 0, allIndexes.length); System.arraycopy(allSizes, 0, newSizes, 0, allSizes.length); newIndexes[allIndexes.length] = u; newSizes[allSizes.length] = insert; allIndexes = newIndexes; allSizes = newSizes; if (insert > 0) { state = 3; } } } if (state < 3) { --state; } } while (state != 0); // 2nd step: // copies the bytecode of the method into a new bytevector, updates the // offsets, and inserts (or removes) bytes as requested. ByteVector newCode = new ByteVector(code.length); u = 0; while (u < code.length) { int opcode = b[u] & 0xFF; switch (ClassWriter.TYPE[opcode]) { case ClassWriter.NOARG_INSN: case ClassWriter.IMPLVAR_INSN: newCode.putByte(opcode); u += 1; break; case ClassWriter.LABEL_INSN: if (opcode > 201) { // changes temporary opcodes 202 to 217 (inclusive), 218 // and 219 to IFEQ ... JSR (inclusive), IFNULL and // IFNONNULL opcode = opcode < 218 ? opcode - 49 : opcode - 20; label = u + readUnsignedShort(b, u + 1); } else { label = u + readShort(b, u + 1); } newOffset = getNewOffset(allIndexes, allSizes, u, label); if (resize[u]) { // replaces GOTO with GOTO_W, JSR with JSR_W and IFxxx // with IFNOTxxx GOTO_W , where IFNOTxxx is // the "opposite" opcode of IFxxx (i.e., IFNE for IFEQ) // and where designates the instruction just after // the GOTO_W. if (opcode == Opcodes.GOTO) { newCode.putByte(200); // GOTO_W } else if (opcode == Opcodes.JSR) { newCode.putByte(201); // JSR_W } else { newCode.putByte(opcode <= 166 ? ((opcode + 1) ^ 1) - 1 : opcode ^ 1); newCode.putShort(8); // jump offset newCode.putByte(200); // GOTO_W // newOffset now computed from start of GOTO_W newOffset -= 3; } newCode.putInt(newOffset); } else { newCode.putByte(opcode); newCode.putShort(newOffset); } u += 3; break; case ClassWriter.LABELW_INSN: label = u + readInt(b, u + 1); newOffset = getNewOffset(allIndexes, allSizes, u, label); newCode.putByte(opcode); newCode.putInt(newOffset); u += 5; break; case ClassWriter.TABL_INSN: // skips 0 to 3 padding bytes v = u; u = u + 4 - (v & 3); // reads and copies instruction newCode.putByte(Opcodes.TABLESWITCH); newCode.length += (4 - newCode.length % 4) % 4; label = v + readInt(b, u); u += 4; newOffset = getNewOffset(allIndexes, allSizes, v, label); newCode.putInt(newOffset); j = readInt(b, u); u += 4; newCode.putInt(j); j = readInt(b, u) - j + 1; u += 4; newCode.putInt(readInt(b, u - 4)); for (; j > 0; --j) { label = v + readInt(b, u); u += 4; newOffset = getNewOffset(allIndexes, allSizes, v, label); newCode.putInt(newOffset); } break; case ClassWriter.LOOK_INSN: // skips 0 to 3 padding bytes v = u; u = u + 4 - (v & 3); // reads and copies instruction newCode.putByte(Opcodes.LOOKUPSWITCH); newCode.length += (4 - newCode.length % 4) % 4; label = v + readInt(b, u); u += 4; newOffset = getNewOffset(allIndexes, allSizes, v, label); newCode.putInt(newOffset); j = readInt(b, u); u += 4; newCode.putInt(j); for (; j > 0; --j) { newCode.putInt(readInt(b, u)); u += 4; label = v + readInt(b, u); u += 4; newOffset = getNewOffset(allIndexes, allSizes, v, label); newCode.putInt(newOffset); } break; case ClassWriter.WIDE_INSN: opcode = b[u + 1] & 0xFF; if (opcode == Opcodes.IINC) { newCode.putByteArray(b, u, 6); u += 6; } else { newCode.putByteArray(b, u, 4); u += 4; } break; case ClassWriter.VAR_INSN: case ClassWriter.SBYTE_INSN: case ClassWriter.LDC_INSN: newCode.putByteArray(b, u, 2); u += 2; break; case ClassWriter.SHORT_INSN: case ClassWriter.LDCW_INSN: case ClassWriter.FIELDORMETH_INSN: case ClassWriter.TYPE_INSN: case ClassWriter.IINC_INSN: newCode.putByteArray(b, u, 3); u += 3; break; case ClassWriter.ITFMETH_INSN: newCode.putByteArray(b, u, 5); u += 5; break; // case MANA_INSN: default: newCode.putByteArray(b, u, 4); u += 4; break; } } // recomputes the stack map frames if (frameCount > 0) { if (compute == FRAMES) { frameCount = 0; stackMap = null; previousFrame = null; frame = null; Frame f = new Frame(); f.owner = labels; Type[] args = Type.getArgumentTypes(descriptor); f.initInputFrame(cw, access, args, maxLocals); visitFrame(f); Label l = labels; while (l != null) { /* * here we need the original label position. getNewOffset * must therefore never have been called for this label. */ u = l.position - 3; if ((l.status & Label.STORE) != 0 || (u >= 0 && resize[u])) { getNewOffset(allIndexes, allSizes, l); // TODO update offsets in UNINITIALIZED values visitFrame(l.frame); } l = l.successor; } } else { /* * Resizing an existing stack map frame table is really hard. * Not only the table must be parsed to update the offets, but * new frames may be needed for jump instructions that were * inserted by this method. And updating the offsets or * inserting frames can change the format of the following * frames, in case of packed frames. In practice the whole table * must be recomputed. For this the frames are marked as * potentially invalid. This will cause the whole class to be * reread and rewritten with the COMPUTE_FRAMES option (see the * ClassWriter.toByteArray method). This is not very efficient * but is much easier and requires much less code than any other * method I can think of. */ cw.invalidFrames = true; } } // updates the exception handler block labels Handler h = firstHandler; while (h != null) { getNewOffset(allIndexes, allSizes, h.start); getNewOffset(allIndexes, allSizes, h.end); getNewOffset(allIndexes, allSizes, h.handler); h = h.next; } // updates the instructions addresses in the // local var and line number tables for (i = 0; i < 2; ++i) { ByteVector bv = i == 0 ? localVar : localVarType; if (bv != null) { b = bv.data; u = 0; while (u < bv.length) { label = readUnsignedShort(b, u); newOffset = getNewOffset(allIndexes, allSizes, 0, label); writeShort(b, u, newOffset); label += readUnsignedShort(b, u + 2); newOffset = getNewOffset(allIndexes, allSizes, 0, label) - newOffset; writeShort(b, u + 2, newOffset); u += 10; } } } if (lineNumber != null) { b = lineNumber.data; u = 0; while (u < lineNumber.length) { writeShort(b, u, getNewOffset(allIndexes, allSizes, 0, readUnsignedShort(b, u))); u += 4; } } // updates the labels of the other attributes Attribute attr = cattrs; while (attr != null) { Label[] labels = attr.getLabels(); if (labels != null) { for (i = labels.length - 1; i >= 0; --i) { getNewOffset(allIndexes, allSizes, labels[i]); } } attr = attr.next; } // replaces old bytecodes with new ones code = newCode; } }





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